DE955254C - Control device for multiple memories in telecommunications, especially telephone systems - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

ISSUED JANUARY 3, 1957

GERMAN PATENT OFFICE

PATENT LETTERING

CLASS 21a ³ GROUP 3201 INTERNAT. CLASS H 04m

110248 VIIIa121 a ^s

Donald Adams Weir and Joseph Rice, London

have been named as inventors

International Standard Electric Corporation, New York, N.Y. (V. St. A.)

Control device for multiple memories in telecommunications, in particular telephone systems

Addendum to patent 951

Patented in the territory of the Federal Republic of Germany on May 25, 19S5

The main patent started on March 24, 1964

Patent application published June 28, 1956

Patent granted on December 13, 1966

The priority of the application in Great Britain on May 25, 1954 has been claimed

The main patent 951 636 relates to a control device for multiple memories in Telecommunications, in particular telephone systems. The message contents are here in binary Shape saved. As multiple storage, for example, magnetic drums with several Storage lanes are used. Every storage lane is a special control element assigned, which is alternately remagnetized with each revolution of the drum, d. H alternately receives the information "1" and "o". This is the cyclical change of this control indicator disturbed by incorrect storage, an alarm device is activated.

As an improvement to the main patent mentioned, an arrangement is proposed in the form that a control element is provided for each individual memory of a multiple memory is, which runs through the tapping device several times before tapping the individual memory

and alternately receives one of two different identifiers on each run.

When using magnetic drums for multiple storage, not everyone will Storage lane, but a control element for each storage section of such a storage lane allocated so that more precise monitoring of the storage processes is possible.

The invention is explained in more detail with reference to the figures. Here shows

Fig. Ι a schematic representation of an arrangement according to the invention, in which a serial storage on the track of a magnetic Drum is made,

FIG. 2 shows the control circuits for the arrangement according to FIG.

3 shows the Welkniormen which are used in the circuits of FIGS.

In the embodiment in Fig. Ι a magneao table drum with magnetizable surface and motor drive used.

Each storage lane on the drum has a number of independent storage sections. These memory sections are guided past a combined head one after the other. Separate storage and pick-up heads can also be used. The switching processes are controlled by the time elements 1 1 and 1 2.

The drum in Fig. Ι is denoted by ι and has the memory lanes 2, 3 and 4, to which the combined head 6 and 7 are assigned. Each combined head has a control circuit allocated. In Fig. 1 only the control circuit 8 is shown, which belongs to the head 7. This Circuit works with all memory sections of a web, and when a memory section is under passes through a head, the control circuit 8 returns to its rest position. Once the The next memory section appears on the head, the control circuit is switched on again.

Most of the switching operations are carried out by the control circuit 8, specifically under the control of pulse cycles, which permanent memories are taken from additional tracks of the drum. As is well known, each lane has a number of independent storages and it is assumed that there are m such storages. Since there are no visible identifiers on the drum tracks that define the individual sections, there is a control track 9, which is also referred to as a marking track. This has a marking or the binary value 1 stored in the longitudinal direction, in each case in the first element of each section. This marking track is assigned to all storage tracks together.

The marking path 9 is assigned a head MH , which is also referred to as a marking head. The. Output signals from this head are applied through an amplifier MPA and the gate GPi to the counter WS , which has as many units m as there are sections on each lane. The gate GP 1 opens at time ί 1, ie at the beginning of an element. When the first section of a web passes the combined head, the counter WS has switched its first unit. The same applies to the following sections and corresponding counter units.

In order to ensure that the counter WS and the marking pulses of the marking tracks stay in step, an additional marking track 10 is provided, which has an individual storage at the beginning of the first sections of all tracks. This causes the storage WS to WS 1 via the amplifier MAA and the gate GP 2 for each revolution of the drum 1. The gate GP 2 is opened in the time element f 2, ie in a part of this element. If there is no incorrect storage, these circuits remain ineffective. A variant of this arrangement consists in a second storage in the second element section of each track section, which is tapped and brings the counter WS to rest position.

There is another Steüerbahn, which is called the time track and has a special marking for each time element. These memories are picked up by the time header CH and fed to the counter CPC via the amplifier CPA and the gate GP 3. The gate GP 3 opens at time ί i. The number of these time elements corresponds to the number of element positions of the sections, and where the number of elements in the individual sections is not equal, the number of time elements corresponds to the memory section with the largest number of elements. This measure cannot cause any malfunctions, since the time pulse counter is in the rest position, specifically in its switch position 5, when a marking pulse occurs via gate GP 4 at time i2.

From Fig. 3 it can be seen that seventeen time elements are provided in each lane, namely EM, the marking element, the elements ES, EC and £ 14 to E 1. The waveforms Pa are demVerstärker MAA (FIG. 1) removed, and the waveforms WS come from the corresponding sections of the counter WS. The waveforms Pm, Pc and Ps are outputs of the counter CPC (Fig. 1). The control pulse parts and * 2, which occur in all elements, are taken from the time pulses via the pulse generator PUF (Fig. 1). This pulse generator generates a narrow pulse 1 1 at the beginning of each pulse, and via a delay element 12 the pulse i2. The control pulses CW are taken from a bistable multivibrator, which is controlled by the pulses * 2 and ti. The latter waveforms are used to control the memory circuit in Fig. 2. iao

Each additional control pulse comes from one of these two 'pulse sources'. If a switching process has to occur in time element 3 of a section, this can only be carried out when the counter CPC has switched its third unit.

As already mentioned, the control circuit 8 works with the sections of the path. These storage devices, which are controlled by the arrangement according to the invention, are used to store various orders. pick up donors and process them in the desired manner. To carry out these memory jobs, corresponding pulses appear on lines UT 1 to UT m. A number of gates Gi to G m are located between these lines and the common control device. These gates, which are shown as circles, each have a number of inputs and all together have one Exit. Each of these gates is opened or conductive when all inputs are simultaneously live.

Each gate emits an output pulse when a section of the web passes the head 7 will. In a sense, these gates represent an electronic version of a call finder or a corresponding multiple switch. When a gate releases an output pulse, causes the control circuit 8 that the stored sum in the corresponding section a 1 will be added. It is well known that such devices are stored on bi ner basis.

To test the switching operations of the circuit 8 and the condition of the track, each section provided with an additional element. This element, which is used for testing purposes, is each assigned to a memory section.

The control circuit 8 contains a display device 13 which is shown separately for the sake of explanation. This takes effect when the pulse Pc occurs in order to add a 1 in the element EC of the section which is just passing the head 7. The comparator 14 is also switched on. The normal position of the element EC is 0, and a 1 is added with each revolution of the drum, so that the element EC alternates between 1 and 0. If this change in marking stays in rhythm, all switching operations are correct. If an error is observed here, the alarm device 15 comes into operation.

In FIG. 2, two rectangles which are drawn together represent a bistable trigger circuit. Three such connected rectangles represent a tristable trigger circuit. All of these flip-flops are marked with F , which are preceded by a corresponding prefix. The circuits that control these flip-flops are marked with the letter /.

The flip-flop 1 F is controlled by the gates G 5 and G 6 from the pick-off amplifier. The switch position 1 F 1 indicates the value 1 when actuated and the switch position 1F2 the value 0. The toggle switch 2 F is an additional control device which responds to the markings by the element EM if 1 is to be added to the existing memory total.

The element EM indicates the value 0 in its rest position, so that the toggle switch ι F is initially set in its switch position 1F2 at the time i ι via the gate G 6. The toggle switch 2 F is in the switch position 2, Fi. The gates Gi, Gm , etc., of which only the gate G ι is shown in Fig. 2 , control the gates Gy and G 8 via a mixing circuit, so that they can only open to the flip-flop 2 F in the second switching position To bring time ii when the marking element is effective.

When the marking element is tapped for the first time, the toggle switch 3 F is set via gate G10 at time i2, since the switch positions 1/2 and 2/1 are effective. If 2/1 is actuated, this causes, since the pulse Pm occurs at the time, the gate Gn to give an output pulse which controls the gate G13 via the mixing gate G12 and the timing element t2 , the flip-flop 4F sets, namely to the Switch position 4F1. The flip-flop 4 F is a bistable control device and causes the spoke * circuit 15 to store a 1 in the marking element. This circuit receives the waveform CW and is controlled by the flip-flop 5 F and only stores when the flip-flop 5 F 1 is switched.

The process of adding to a binary digit is achieved by inverting all digits, including the first digit 0. 'Therefore, during the. Waveform WM 1, which has positive pulses during each section of the web, the controller 4F switched so that when a count pulse is tapped, 1 is stored, since 0 and 0 are tapped as 1, up to the first 0. If therefore 1 is removed and the toggle switch 1 F goes into the switch position 1 F 1, the gate G14 opens because ifi is effective. In this state, the impulses of waveform WM 1 are positive and control line 3/1 is effective. The toggle switch 4 F is thus in the switch position 4 F 2, and 0 is therefore stored. If, on the other hand, 0 is tapped and the toggle switch ι F goes into switch position 2, gate G15 opens and brings the toggle switch 4 F into its switch position 1. This saves 1.

As already described, this inversion process is only continued until a 0 is converted. This is the case because tapping 0 brings the toggle switch 1 F into its second switching position, which brings the toggle switch 3 F into its second switch position via gate G16, WMi, t2 and 1/2 and gate G17. This ends the reversal processes, and the toggle switch 1 F controls the first switch position of the toggle switch 4-F in its first switch position, via gate G18, and the second switch position of the toggle switch 1 F controls the toggle switch 4 F via gate G19 in their second switch position. For this reason, the rest of the value is tapped without change.

In order to prevent storage if no change of a number is required, the toggle

circuit 5 F provided, which has operated its second switch position in the normal state. In the rest position, the tristable toggle switch 7 F has assumed its second switch position, so that an input is effective at gate G 20. If it is necessary to change a tapped number, the toggle switch 5 F is brought into its first switch position, which switches on the circuit 15. This happens depending on the marking element, if at this point in time a memory pulse from a client is tapped. This occurs when the gate G 21 opens and the toggle switch 5 F is brought into its first switching position via the gates G 22, G 23 and G 20.

As a result, the storage circuit 15 becomes effective. At the beginning of the pulse train WM 1, the flip-flop 2 F goes back to the second switch position.

In the same way, the flip-flop 5 F in

brought the first switch position, through the gate G 24, when the value 1 is tapped. This means that the toggle switch 5 F moves into the first switch position in order to enable storage during the first test of a section after the need to add a 1 has been determined. At the end of the section, the toggle switch 5 F is brought into its second switching position via pulses Ps and gate G 25.

During the following rotation of the drum, during which the addition process is maintained, the time marking (the value 1) is recorded in the element EM , so that although the toggle switch 2 F is in its first switch position, the toggle switch 5 F does not return with each revolution can be brought into its first switch position and therefore no further storage takes place. The flip-flop 5 F is also used in connection with the display device.

After the addition processes have ended, the flip-flop 2 F cannot return to its first switching position. Since the toggle switch 4.F is brought into the second switch position by Pm

the time stamp is removed by storing the value 0 in the element EM.

The element EC is used to display the switching processes during the test. After every turn

rotation of the drum, the polarity of the signal in the element EC is reversed by adding the value 1. Precautions are taken to determine if the reversal has occurred. More stores will be

prevented if an incorrect storage was detected, and an alarm device is activated made.

It is advantageous to assume that the display device is already switched on. When the start button KR is pressed, the tristable toggle switch 7 F goes into its switch position 3. After the occurrence of the next pulse Pa, which indicates the start of a path, switch position 2 of the toggle switch 7 F becomes effective and prepares the toggle switch 5 F , allow the storage. At the same time, Pa actuates the second switch position of toggle switch 6 F.

In this switching state, the content of the EIe Mentes EC is equal to the value 0 and thus switching position 2 of the toggle switch ι F is actuated. The switch position ι of the toggle switch 7 F is not effective because the switch position 2 of the toggle switch 6F and the switch position 2 of the toggle switch ι F none of the gates G 26 and G 27 can open. The switch position 2 of the toggle switch 1 F causes the operation of the switch position 1 of the toggle switch 4F via the gate G 28, because of the pulses Pc, so that a 1 is stored in the element EC. The storages have been converted during the first revolution of the drum.

When the pulses Pa occur again at the beginning of the next revolution, the first switch position of the toggle switch 6 F is switched on again. Since the previously stored values 1 are thus tapped by the element EC , the first switch position of the toggle switch 7 F is not actuated. Now, the values of F 0 is stored on the flip-flop circuit 4, because the second switching position of the flip-flop 4F by the pulses Pc via gate G is actuated 29th

The switching operations continue, the flip-flop switch 6 F toggles with each revolution and the display elements also change their polarity.

If there is no match between the toggle switch 6 F and the element EC , the toggle switch 7 F switches to switch position i. If an incorrect storage occurs and the value 1 is tapped instead of 0, the control lines 6/2 and 1/1 open gate G 26. In the other case, if the value 0 is tapped instead of 1, gate G 27 opens via the control lines 6 / 1 and if2. In any case, the toggle switch 7 F is made effective via the gates G 30 and G 31 i ° 5. The control pulses Pc at gate G 31 ensure that the switch position 1 of the toggle switch 7 F can only be operated during the time element EC . When the switch position ι of the toggle switch 7 F is actuated, a relay AL responds to give an alarm. With the switch position 1 of the toggle switch 5 F , further storage is prevented.

The section in which an error was detected is determined by the content of the elements "5 EC . If the track with the pulses Pa has been tapped, the section in which the error was detected is the first to be switched over of the polarity in the element EC . All elements EC which are tao in the correct switching state have either the value 1 or θ and the wrong ones have the value 0 or 1. If no difference in polarity is found in the element EC , the in Question coming section the first within a train.

Claims (5)

By reading the section can be determined by the switch position of the counter, z. B. the pulse series Pc up to the change in which element EC has been noted. The counter could then control the reading of that section if so desired. It is noted in this regard that the display element EC always lies at the end of a section and that this is followed by a distance ES . The distance is provided ίο for runs when the storage device is switched off. Cathode ray tubes, ferroelectric or ferromagnetic matrices are also possible as storage elements. _lg PATENT APPLICATIONS: i. Control device for multiple memories, which receive the message content in binary form, in telecommunications, in particular telephone systems according to Patent 951 636, characterized in that a control element is provided for each individual memory of a multiple memory (section Ei to EM in Fig. 3), which before runs through the tap of the individual memory several times on the tapping device and alternately receives one of two different identifiers (O or 1) with each run. 2. Control device according to claim 1, characterized in that as a multiple memory a magnetic drum (1 in Fig. 1) with multiple tracks (z. B. 2 to 4 in Fig. 1) is used will. 3. Control device according to claim 2, characterized in that each path in a Number of sections is subdivided and each section as an individual memory to accommodate one Information serves. 4. Control device according to claim 3, characterized in that each section is assigned a control element (EC in Fig. 3), in which each. Rotation of the drum as a control indicator, the binary number values "1" and "o" are stamped alternately. 5. Control device according to Arfspruch4, characterized in that when the control characters are picked up, an alarm device (AL in Fig. 2) is made effective when the sequence of control characters is disturbed. 1 sheet of drawings © 609547/199 6.56 (609 726 12.56)